Large scale genotyping of disease and a diagnostic test for spinocerebellar ataxia type 6

ABSTRACT

The present invention provides a method of screening individuals at risk for developing diseases caused by trinucleotide repeat sequence instability. Specifically, the present invention is drawn to screening individuals at risk for developing autosomal dominant spinocerebellar ataxia type 6 by determining the length of a CAG trinucleotide repeat in the α 1A  calcium channel gene of the individual. In addition, there is provided a method of identifying genes which are disease-causing due to trinucleotide repeat sequence instability by large scale genotyping.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. Ser. No. 09/093,273 filed Jun. 8, 1998, which is a divisional of U.S. Ser. No. 08/779,801 filed Jan. 7, 1997, now U.S. Pat. No. 5,853,995.

FEDERAL FUNDING LEGEND

This invention was produced in part using funds obtained through a grant from the Department of the Army. Consequently, the federal government has certain rights in this invention.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to the fields of molecular genetics and diagnosis of genetic diseases. More specifically, the present invention relates to a large scale genotyping of diseases and diagnostic tests and kits for same.

2. Description of the Related Art

Expansion of repeat sequences involving the trinucleotides CAG, CTG, CGG or GAA has been shown to be the primary cause of several neurological disorders¹. Among them, CAG repeat expansions have been associated with a group of neurodegenerative disorders including Huntington disease², spinobulbar muscular atrophy³, spinocerebellar ataxia type 1 (SCA1)⁴, spinocerebellar ataxia type 2 (SCA2)⁵⁻⁷, spinocerebellar ataxia type 3/Machado-Joseph disease (SCA3/MJD)⁸, and dentatorubral-pallidoluysian atrophy/Haw-River syndrome⁹. All these disorders are progressive diseases leading to degeneration of the neurons in central nervous system. The CAG repeats in the respective genes show length polymorphism in the human population, typically, not exceeding 40 repeats. In affected individuals, the expanded alleles contain 36-121 repeats¹⁰.

CAG repeat expansions are much smaller than t h e hundreds or thousands of repeats often seen in diseases with CGG, CTG, and GAA expansions¹¹⁻¹⁴. The expanded CAG alleles show variable degrees of instability in both germline and somatic tissuesl^(15,16). Intergenerational changes of the CAG repeat size are often biased toward further expansion, particularly if paternally transmitted, providing the molecular basis for anticipation. The CAG repeat arrays in these diseases are located in the coding regions of the involved genes and are translated into polyglutamine tracts in the protein products¹⁷. It has been postulated that an expansion of the polyglutamine tract produces a gain of function in the protein product in each disease accounting for the dominant inheritance. Based on the relatively uniform characteristics of diseases caused by CAG repeat expansions, it has been speculated that other neurodegenerative diseases with similar clinical characteristics may have expansions of CAG repeats. Indeed, a study by Trottier and colleagues demonstrated that an antibody against a polyglutamine tract detects abnormally large proteins in tissues from patients with either SCA2 or spinocerebellar ataxia type 7 (SCA7), suggesting that the mutation responsible for SCA2 and SCA7 is an expansion of a polyglutamine repeat tract¹⁸.

The prior art is deficient in the lack of effective means for the large scale genotyping of genetic diseases and diagnostic tests and kits for diagnosing such diseases. The present invention fulfills this long-standing need and desire in the art.

SUMMARY OF THE INVENTION

A polymorphic CAG repeat was identified in the human α_(1A) voltage-dependent calcium channel subunit. To demonstrate that expansion of this CAG repeat could be the cause of an inherited progressive ataxia, a large number of unrelated controls and ataxia patients were genotyped. Eight unrelated patients with late onset ataxia had alleles with larger repeat numbers (21-27) compared to the number of repeats (4-16) in 475 non-ataxia individuals. Analysis of the repeat length in families of the affected individuals revealed that the expansion segregated with the phenotype in every patient. Six isoforms of the human α_(1A) calcium channel subunit were identified. The CAG repeat is within the open reading frame and is predicted to encode glutamine in three of the isoforms. Thus, a small polyglutamine expansion in the human α_(1A) calcium channel is most likely the cause of a newly classified autosomal dominant spinocerebellar ataxia, SCA6.

In one object of the present invention, there is provided a method of screening individuals at risk for developing diseases caused by trinucleotide repeat sequence instability, comprising the steps of: amplifying genomic DNA trinucleotide repeat sequences in a sample from an individual by polymerase chain reaction using one or more oligonucleotide primers; restricting said amplified genomic DNA trinucleotide repeat sequences with a restriction enzyme; separating said restricted amplified genomic DNA trinucleotide repeat sequences by electrophoresis to form a sample electrophoresis pattern; labeling a probe capable of detecting said amplified genomic DNA trinucleotide repeat sequences in said sample; hybridizing said sample of restricted, amplified genomic DNA trinucleotide repeat sequences with a first aliquot of said labeled probe under hybridizing conditions to produce a sample hybridization pattern for said sample genomic DNA trinucleotide repeat sequence; amplifying a control genomic DNA trinucleotide repeat sequence by polymerase chain reaction using said one or more oligonucleotide primers, wherein said control genomic DNA trinucleotide repeat sequence is from non-diseased source; restricting said control genomic DNA trinucleotide repeat sequence with a restriction enzyme; separating said restricted control genomic DNA trinucleotide repeat sequence b y electrophoresis to form a control electrophoresis pattern; combining said restricted control genomic DNA trinucleotide repeat sequence with a second aliquot of said probe under hybridizing conditions to form a control hybridization pattern for said genomic DNA trinucleotide repeat sequence; comparing said sample hybridization pattern for said sample genomic DNA trinucleotide repeat sequence to said control hybridization pattern for said control genomic DNA trinucleotide repeat sequence; and determining whether said individual to be tested may be at risk for developing diseases caused by trinucleotide repeat sequence instability, wherein if said sample genomic DNA trinucleotide repeat sequence is larger than said control genomic DNA trinucleotide repeat sequence, said individual may be at risk for developing diseases caused by trinucleotide repeat sequence instability.

In another object of the present invention, there is provided a method of identifying genes in which a disease-causing allele is due to trinucleotide repeat sequence instability, comprising the steps of: screening a library with an oligonucleotide having a triplet base repeat; identifying clones which have said triplet base repeat; sequencing said identified clones to determine sequences of nucleotides flanking said triplet base repeat; synthesizing primers complementary to said sequences of nucleotides flanking said triplet base repeat; isolating DNA from a large sampling of individuals, including diseased and non-diseased individuals; amplifying said isolated DNA with said primers to produce amplified triplet base repeat regions; determining a number of triplet base repeats in said triplet base repeat region for each of said individuals in said large sampling; determining whether triplet base repeat expansions are observed at a relatively high frequency in diseased individuals but are absent or occur at very low frequency in non-disease individuals, wherein if triplet base repeat expansions are observed at a relatively high frequency in diseased individuals but are absent or occur at very low frequency in non-disease individuals, it is likely that a disease-causing allele is due to trinucleotide repeat sequence instability.

Other and further aspects, features, and advantages of the present invention will be apparent from the following description of the presently preferred embodiments of the invention given for the purpose of disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the matter in which the above-recited features., advantages and objects of the invention are attained and can b e understood in detail, more particular descriptions of the invention may be had by reference to certain embodiments which are illustrated in the appended drawings. These drawings form a part of the specification. It is to be noted, however, that the appended drawings illustrate preferred embodiments of the invention and therefore are not to be considered limiting in their scope.

FIG. 1 shows isoforms of the human α_(1A) voltage-dependent Ca²⁺ channel.

FIG. 1A shows that all the different isoforms have been observed in at least two independent cDNA clones. The “ ” represents a 94 base pair nucleotide variation and the “ ” represents a 36 bp deletion. The site of the GGCAG insertion is indicated by a vertical bar and the position of the glutamine tract (poly Q) is shown as “ ”. The amino acid changes affected by these variations are shown in FIG. 2. Only the isoforms with the GGCAG insertion have the extended open reading frame.

FIG. 1B shows the sequences flanking the stop codon of the human Ca²⁺ channel isoforms BI-1 and BI-1 (GGCAG). The top and bottom letters indicate the respective amino acid encoded by the sequence. The stop codon is indicated by the TAN nucleotide. The nucleotide “N” is a ‘G’ nucleotide which has a decreased size of the “G” peak following an “A” peak, a characteristic of the FS Taq enzyme in dye terminator sequencing chemistry from Applied Biosystem. It was confirmed that this indeed is a “G” nucleotide when the reverse strand was sequenced. The complementary sequence of TAG, CTA is underlined.

FIGS. 2A-2C show the sequence comparison between the rabbit (BI-1) and human a₁ voltage-dependent Ca²⁺ channel. The partial human cDNA sequence is a combination of two overlapping clones of 3.6 kb representing the largest deduced open reading frame. Identical amino acids are indicated by a “-” symbol and gaps in the alignment are represented by the “.” symbol. The human and rabbit BI-1 cDNAs share 90-94% amino acid identity depending on the isoforms. Since the full-length human α_(1A) voltage-dependent Ca²⁺ channel has not determined, the amino acid strands in the rabbit BI-1 sequence were numbered as reference (OCCCBI-1 in GenBank). Hypothetical insertion of the GGCAG nucleotides into the rabbit BI-1 isoform (accession No X57476) extends its deduced peptide reading frame by 237 amino acids with the stop codon in the rabbit and human at identical positions. In this deduced reading frame the glutamine repeat is underlined starting at amino acid position 2328 in the human and the rabbit cDNA sequences. Without this insertion, the rabbit and human BI-1 isoforms deduced reading frame stops at amino acid position 2273 as indicated by “*” (listed here as 2275 due to introduction of 2 alignment gaps). The amino acids which vary in the isoforms corresponding to the V1, V2 , V3 variations and GGCAG insertion are boxed. The V3 isoform has a truncated 3′ region with a poly A⁺ tract. The sequences of the respective isoforms have been deposited in GenBank (accession numbers: U79663, U79664, U79665, U79666 U79667 and U79668).

FIG. 3 shows the northern analysis of human α_(1A) voltage-dependent Ca²⁺ channel expression. Hybridization was carried out with the S-5 cDNA as probe. A distinct band of 8.5 kb was present in brain mRNA with a smear pattern specific to this probe and not detected using the β-actin probe. The smearing in the mRNA from brain may reflect cross hybridization with the various alternative spliced forms or some degradation.

FIG. 4 shows the analysis of the PCR-amplified products generated with S-5-F1 and S-5-R1 primers flanking the CAG repeat in families with cerebellar ataxia.

FIG. 4A shows the expanded allele with 27 repeats in the four affected individuals (I.2, II.3, II.5, and II.7) from the INSCA kindred but in none of the asymptomatic family members.

FIG. 4B shows that the expanded allele of 22 CAGs repeats is observed in all five affected members (II.1, II.2, II.3, III.1 and III.2) of the MS2SCA kindred.

FIG. 4C shows that in the MDSCA kindred an aberrant size allele of 23 CAG repeat was present in two brothers (II.1 and II.3) and a sister (II.2) with clinical ataxia but not in the asymptomatic daughter of II.1.

FIG. 4D shows the SISCA family where two affected members (IV.1 and III.7) separated by five meiotic events share the same number of 22 CAG repeats on their larger alleles. Tracing this allele through the pedigree indicates that their affected progenitors (III.5, II.2, II.4 and I.2) most likely have this expanded allele.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is directed to a method of screening individuals at risk for developing diseases caused by trinucleotide repeat sequence instability, comprising the steps of: amplifying genomic DNA trinucleotide repeat sequences in a sample from a n individual to be tested by polymerase chain reaction using one or more oligonucleotide primers; labeling a probe capable of detecting said amplified genomic DNA trinucleotide repeat sequences in said sample; combining said sample of amplified genomic DNA trinucleotide repeat sequences with a first aliquot of said labeled probe under hybridizing conditions to produce a sample hybridization pattern for said sample genomic DNA trinucleotide repeat sequence; amplifying a control genomic DNA trinucleotide repeat sequence by polymerase chain reaction using said one or more oligonucleotide primers, wherein said control genomic DNA trinucleotide repeat sequence is from non-diseased source; combining said control genomic DNA trinucleotide repeat sequence with a second aliquot of said probe under hybridizing conditions to form a control hybridization pattern for said genomic DNA trinucleotide repeat sequence; comparing said sample hybridization pattern for said sample genomic DNA trinucleotide repeat sequence to said control hybridization pattern for said control genomic DNA trinucleotide repeat sequence; and determining whether said individual to b e tested may be at risk for developing diseases caused by trinucleotide repeat sequence instability, wherein if said sample genomic DNA trinucleotide repeat sequence is larger than said control genomic DNA trinucleotide repeat sequence, said individual may be at risk for developing diseases caused by trinucleotide repeat sequence instability.

The present invention is additionally directed to a method of identifying genes in which a disease-causing allele is due to trinucleotide repeat sequence instability, comprising the steps of: screening a library with an oligonucleotide having a triplet base repeat; identifying clones which have said triplet base repeat; sequencing said identified clones to determine sequences of nucleotides flanking said triplet base repeat; synthesizing primers complementary to said sequences of nucleotides flanking said triplet base repeat; isolating DNA from a large sampling of individuals, including diseased and non-diseased individuals; amplifying said isolated DNA with said primers to produce amplified triplet base repeat regions; determining a number of triplet base repeats in said triplet base repeat region for each of said individuals in said large sampling; determining whether triplet base repeat expansions are observed at a relatively high frequency in diseased individuals but are absent or occur at very low frequency in non-disease individuals, wherein if triplet base repeat expansions are observed at a relatively high frequency in diseased individuals but are absent or occur at very low frequency in non-disease individuals, it is likely that a disease-causing allele is due to trinucleotide repeat sequence instability.

In accordance with the present invention there may b e employed conventional molecular biology, microbiology, and recombinant DNA techniques within the skill of the art. Such techniques are explained fully in the literature. See, e.g., Maniatis, Fritsch & Sambrook, “Molecular Cloning: A Laboratory Manual (1982); “DNA Cloning: A Practical Approach,” Volumes I and II (D.N. Glover ed. 1985); “Oligonucleotide Synthesis” (M. J. Gait ed. 1984); “Nucleic Acid Hybridization” [B. D. Hames & S. J. Higgins eds. (1985)]; “Transcription and Translation” [B. D. Hames & S. J. Higgins eds. (1984)]; “Animal Cell Culture” [R. I. Freshney, ed. (1986)]; “Immobilized Cells And Enzymes” [IRL Press, (1986)]; B. Perbal, “A Practical Guide To Molecular Cloning” (1984).

Therefore, if appearing herein, the following terms shall have the definitions set out below.

A “vector” is a replicon, such as plasmid, phage or cosmid, to which another DNA segment may be attached so as to bring about the replication of the attached segment. A vector is said to b e “pharmacologically acceptable” if its administration can be tolerated by a recipient mammal. Such as agent is said to be administered in a “therapeutically effective amount” if the amount administered is physiologically significant. An agent is physiologically significant if its presence results in a change in the physiology of a recipient mammal. For example, in the treatment of retroviral infection, a compound which decreases the extent of infection or of physiologic damage due to infection, would be considered therapeutically effective.

A “DNA molecule” refers to the polymeric form of deoxyribonucleotides (adenine, guanine, thymine, or cytosine) in either single stranded form, or a double-stranded helix. This term refers only to the primary and secondary structure of the molecule, and does not limit it to any particular tertiary forms. Thus, this term includes double-stranded DNA found, inter alia, in linear DNA molecules (e.g., restriction fragments), viruses, plasmids, and chromosomes. In discussing the structure herein according to the normal convention of giving only the sequence in the 5′ to 3′ direction along the nontranscribed strand of DNA (i.e., the strand having a sequence homologous to the mRNA).

A DNA “coding sequence” is a double-stranded DNA sequence which is transcribed and translated into a polypeptide in vivo when placed under the control of appropriate regulatory sequences. The boundaries of the coding sequence are determined by a start codon at the 5′ (amino) terminus and a translation stop codon at the 3′ (carboxyl) terminus. A coding sequence can include, but is not limited to, prokaryotic sequences, cDNA from eukaryotic mRNA, genomic DNA sequences from eukaryotic (e.g., mammalian) DNA, and even synthetic DNA sequences. A polyadenylation signal and transcription termination sequence will usually be located 3′ to the coding sequence.

The term “oligonucleotide”, as used herein in referring to the probe of the present invention, is defined as a molecule comprised of two or more ribonucleotides, preferably more than three. Its exact size will depend upon many factors which, in turn, depend upon the ultimate function and use of the oligonucleotide.

The term “primer” as used herein refers to an oligonucleotide, whether occurring naturally as in a purified restriction digest or produced synthetically, which is capable of acting as a point of initiation of synthesis when placed under conditions in which synthesis of a primer extension product, which is complementary to a nucleic acid strand, is induced, i.e., in the presence of nucleotides and an inducing agent such as a DNA polymerase and at a suitable temperature and pH. The primer may be either single-stranded or double-stranded and must be sufficiently long to prime the synthesis of the desired extension product in the presence of the inducing agent. The exact length of the primer will depend upon many factors, including temperature, the source of primer and the method used. For example, for diagnostic applications, depending on the complexity of the target sequence, the oligonucleotide primer typically contains 15-25 or more nucleotides, although it may contain fewer nucleotides.

As used herein, the terms “restriction endonucleases” and “restriction enzymes” refer to bacterial enzymes, each of which cut double-stranded DNA at or near a specific nucleotide sequence.

The labels most commonly employed for these studies are radioactive elements, enzymes, chemicals which fluoresce when exposed to ultraviolet light, and others. A number of fluorescent materials are known and can be utilized as labels. These include, for example, fluorescein, rhodamine, auramine, Texas Red, AMCA blue and Lucifer Yellow. A particular detecting material is anti-rabbit antibody prepared in goats and conjugated with fluorescein through an isothiocyanate.

The following examples are given for the purpose of illustrating various embodiments of the invention and are not meant to limit the present invention in any fashion.

EXAMPLE 1

Isolation of S-5 cDNA

The isolation of the S-5 cDNA was carried out by screening a primary human brain cDNA library with a radiolabeled oligonuclcotide probe (GCT)₇. The human brain cDNA was oligo-d(T) primed using Guber and Hoffman methodology⁴⁴ with mRNA purchased from Clontech (Palo Alto, Calif.). The cDNA library was constructed with Not I restriction linker for cloning into IZAP II vector. The library was plated at a density of 1000 plaques per 150 mm Luria broth agar plates. A total of 150,000 primary clones were screened. Hybridization with a radiolabeled oligonucleotide probe (GCT)₇ was carried out at 55° C. using standard aqueous hybridization solution⁴⁵. The filters were washed 3 times for 30 minutes each a t 55° C. in 2×SSC and 0.1% SDS. Hybridizing clones were purified for plasmid rescue. Plasmid DNAs was isolated using an AutoGen 740 instrument and were sequenced using ABI kit and protocol on a ABI-373A sequencer. Sequencing of the cDNAs were carried out to confirm the presence of the triplet repeat sequence. The S-5 cDNA was one out of the 387 unique recombinant cDNAs obtained by this approach. Additional clones of the U-1A calcium channel were isolated by using the S-5 cDNA as probe. In addition to the above human brain cDNA library, a commercial human fetal brain cDNA library with Eco RI cloning site from Strategene (La Jolla, Calif.) was screened and the identified clones from the library were used to reconstruct the 3′ region from the Not I site to the poly (A) tract.

EXAMPLE 2

PCR Analysis

The degree of CAG length polymorphism in the α_(1A) calcium channel was determined by the following primers: S-5-F1 (5′-CACGTGTCCTATTCCCCTGTGATCC-3′) (SEQ ID NO:1) and S-5-R1 (5′-TGGGTACCTCCGAGGGCCGCTGGTG-3′) (SEQ ID NO:2), though an y appropriate primers based on the sequence of the α_(1A) calcium channel gene may be used for this purpose. For each reaction, 5 pmol of each primer was end-labeled with 1 mCi of [γ-³²P]ATP using 0.05 unit of polynucleotide kinase for 30 minutes. Each PCR analysis contained 20 ng of genomic DNA mixed with 5 pmol each of radiolabeled S-5-R1 and S-5-F1 primers in a total volume of 25 ml containing 0.25 unit of Taq polymerase, 125 μM dNTP, 10 mM Tris pH 8.9, 2.5 mM MgCl₂, 30 mM KCl, and 3.5% (V/V) glycerol. The samples were denatured at 95° C. for 3 minutes, followed by 28 cycles of denaturation (94° C., 25 seconds), annealing (68° C., 30 seconds) and extension (72° C., 2 minutes). Fifteen ml of formamide loading dye was added to the reaction, the mixture was denatured for 20 minutes at 95° C. Seven ml were electrophoresed through a 6% polyacrylamide/8 M urea gel. Alleles sizes were determined b y comparing migration relative to an M13 sequencing ladder. Control DNAs used included 65 samples from the CEPH families; 125 unrelated controls provided by various colleagues in the department of Molecular and Human Genetics; 160 samples from diabetic sibling pairs; 41 sporadic breast cancer cases; 42 from Parkinson index cases; 24 from dystonia index cases and 18 sporadic Alzheimer cases.

EXAMPLE 3

Northern analysis

The northern blot containing poly A⁺ RNA from multiple human tissues was purchased from Clonetech. 200 ng of S-5 cDNA insert was radiolabeled with [α-³²P]dCTP using a random labelling kit from Pharmacia. The probe was hybridized overnight at 65° C. according to the protocol recommended by Clonetech. The filter was washed 3 times at 68° C. for 30 minutes each in 0.1×SSC, 0.1% SDS and then exposed to X-ray film. Lower stringency washes at 68° C. at 0.5×SSC and 0.1% SDS gave many more bands in different tissues suggesting cross reaction with other calcium channel genes.

EXAMPLE 4

Linkage Analysis

Inspection of the genotype data shows a clear association between an increased number of CAG repeats and the ataxia phenotype. Of the 133 ataxia patients, eight had repeat lengths greater than 20, whereas none of the controls had repeat lengths greater than 16. This association was assessed statistically using a 2×2 table comparing the presence of expansions in ataxia cases versus controls. The level of significance was determined using Fisher's exact test.

Haplotype analysis was used to show that the expansion and disease are transmitted together. To model the situation of a single locus with both a phenotype (ataxia) and a polymorphism (expansion): two loci were used, one disease locus and one polymorphism, completely linked and in complete linkage disequilibrium. The haplotype frequencies were calculated b y assuming all 133 of the cases suffer from some kind of dominantly inherited ataxia. There should, therefore, be one disease causing mutation for each case. Eight of these mutations (approximately 6%) were caused by CAG repeat expansions; the other 94% were caused by other mutations, either non-expansion mutations in this gene or mutations in other genes. The additional information needed to calculate the haplotype frequencies is the population frequency of dominant ataxia at unknown loci. The higher the estimate of this frequency the lower the lod scores. A conservative number of 1 in 500 was used for this analysis which places the gene frequency at 1 in 1000. The four haplotype frequencies are then: 0.999 (no ataxia-no expansion), 0.0 (no ataxia-expansion), 0.00094 (ataxia-no expansion), and 0.00006 (ataxia-expansion). These haplotype frequencies were used to calculate the lod scores in the four ataxia families using the FASTLINK version 3.0P software programs. The affection status and genotypes were set for all patients, while unaffected and ungenotyped individuals were specified as unknown affected status and unknown genotype.

To identify diseases which are caused by an expansion of a CAG repeat, a large scale genotyping survey was performed on using polymorphic CAG repeats and DNA samples from patients with late onset neurodegenerative diseases. The present invention reports that the human homolog of the rabbit x 1 A voltage-dependent calcium channel BI-1 gene contains a polymorphic CAG repeat sequence which is expanded in a fraction of patients diagnosed with autosomal dominant cerebellar ataxia. These results indicate that the expansion of a CAG repeat predicted to encode for polyglutamine in the human α_(1A) voltage-dependent Ca²⁺ channel gene is the apparent cause for one form of cerebellar ataxia.

EXAMPLE 5

CAG Repeats in the Human α_(1A)-Calcium Channel Subunit

To identify genes containing trinucleotide repeat sequences, an unamplified human brain cDNA library was screened using a (GCT)₇ repeat oligonucleotide as a probe. This screen identified 387 cDNA clones determined to be independent based on sequence analysis. The repeat sizes in these clones ranged from 4 to 21. Partial cDNA clones corresponding to the dentatorubral-pallidoluysian atrophy/Haw-River⁹ and Machado-Joseph disease genes were isolated in this screen. cDNA clones corresponding to the SCA1, SCA2, and Huntington disease genes were not isolated in this screen, most likely because the CAGrepeat in each of these genes is located in the 5′ region of a large transcript and the cDNA library screened is biased for 3′ cDNA termini given that it was generated using oligo-d(T) priming.

The first clone examined extensively was a cDNA designated S-5 that contained 13 CAG repeats. The deduced peptide sequence of this 1.2 kb cDNA has 90% amino acid identity to the BI-1 isoform of the rabbit α_(1A) A voltage-dependent Ca²⁺ channel (also known as P/Q-type Ca²⁺ channel) suggesting that the S-5 clone is a partial cDNA of the human homolog¹⁹. The deduced human peptide sequence is also 90% identical to the rat brain α_(1A) Ca²⁺ channel subunit²⁰. Partial human cDNA sequence corresponding to rabbit BI-1 amino acid position 722-1036 was previously reported to share 92% and 82% with the rabbit and rat α_(1A) subunit of calcium channel, respectively²¹. The cDNA of the present invention contains coding sequence which corresponds to the carboxy terminus region of the rabbit protein beginning at amino acid position 1325. The sequence data suggest that the cDNA isolated encodes the human α_(1A) subunit of the calcium channel.

Using the somatic cell hybrid mapping panel #2 from Corriel, the α_(1A) Ca²⁺ channel was localized to human chromosome 19 by sequence tag site (STS) mapping. Diriong et al.²², have reported the mapping of the α_(1A) Ca²⁺ channel subunit to human chromosome 19p13 using a partial cDNA clone. The gene symbol of this locus was designated CACNL1A4²². A partial human cDNA, (corresponding to rabbit BI-1 nucleotide position 6487-7165) of the CACNL1A4 gene was reported by Margolis et al.²³ and was shown to map to chromosome 19. A report describing the full-length sequence of the human CACNL1A4 gene was published recently by Ophoff and collegues²⁴.

In rabbit, two isoforms (BI-1 and BI-2) of the α_(1A) calcium channel subunit have been identified¹⁹. These isoforms differ from each other in the carboxy terminus sequence where BI-2 has an additional 151 amino acids. These isoforms are believed to result from an insertion-deletion of 423 nucleotides. The presence of the 423 nucleotides in BI-1 introduces a stop codon which leads to the shorter, 2273 amino acid isoform. In rat brain, at least four alternatively spliced isoforms of the α_(1A) Ca²⁺ channel gene have been observed, but the sequence of only one isoform has been reported²⁰.

Comparison between the rabbit and human sequences revealed that the CAG repeat was conserved and was located in the deduced 3′ untranslated region of the rabbit α_(1A) Ca²⁺ channel BI-1 and the S-5 cDNAs. The finding of a high degree of identity (84% identity over 700 nucleotides) between the 3′ untranslated region of the rabbit BI-1 isoform and the human S-5 clone of the present invention, raised the possibility that additional splice variants may occur and that some may contain an open reading frame in which the CAG repeat is translated. To examine this, the primary human cDNA library and a commercial fetal brain cDNA library was rescreened using the S-5 cDNA as probe. In total, 17 additional clones were isolated, and careful sequence analysis of these clones allowed identification of several alternatively spliced isoforms of the carboxyl region of the human α_(1A) Ca²⁺ channel (FIG. 1A). In particular, five of these cDNAs contain a 5 base pair (GGCAG) insertion prior to the TAG stop codon of the S-5 cDNA (FIG. 1B). Clones with this 5 base pair insertion have an extended deduced open reading frame of an additional 239 amino acids in the human gene. Hypothetical insertion of this 5 base pair sequence into the rabbit BI-1 calcium channel at amino acid position 2273 extends its deduced reading frame by 23 7 amino acids, and the peptide homology to the human sequence remains highly conserved (80% identity) arguing for the presence of such an isoform in the rabbit brain (see FIGS. 2A-2C). In this BI-1 (GGCAG) isoform, the CAG repeat encodes for polyglutamine starting at amino acid position 2328 in the human and rabbit α_(1A) calcium channel gene.

Additional isoforms of the human α_(1A) Ca²⁺ channel gene were also observed in the other clones. To ensure that none of these resulted from cloning artifacts, at least two independent clones for each isoform were isolated and sequenced. In total, six variants were observed including the variant identical to the rabbit BI-1 isoform also designated BI-1 for human. The variant designated BI-1(V1) has a 94 base pair sequence which differs at the nucleotide level from BI-1 but is homologous at the amino acid level. This variant has also been described in rabbit¹⁹. The BI-1(V1) isoform isolated in this study is 99.8% identical to the deduced peptide sequence described by Ophoff et al.²⁴. There are three differences involving amino acids at positions 1460 (Ala to Gly), 1605 (Ala to Val), and 1618 (Ala to Val). The amino acids at these positions in the deduced sequence are consistent in several clones analyzed and are identical to the rabbit and rat α_(1A) Ca²⁺ channel subunit deduced amino acids. The BI-1 and the BI-1(V1) isoforms are observed in combination with the GGCAG insertion (SEQ ID NO.3 and SEQ ID NO:4). Additional splice variants include BI-1(V2)-GGCAG (SEQ ID NO.5) which has a 36 nucleotide deletion and a variant with a truncated 3′ region BI-1-(V2,V3) (FIG. 1A). The identified clones have different combinations of these variants with identical flanking sequences in the non variant segment thereby ruling out cloning artifacts.

Consistent with the presence of multiple isoforms, northern analysis at high hybridization stringency with the S-5 cDNA gave a single band of 8.5 kb overlaying a smear above and below the predominant size mRNA in brain (FIG. 3). At lower hybridization stringency, many additional bands were observed in all tissues suggesting cross hybridization to other types of calcium channels (data not shown). All of the clones from this human brain library, which range from 1.2 to 3.1 kb in size, represent only the carboxyl region of the human α_(1A) Ca²⁺ channel subunit. The CAG repeat in the respective adult brain cDNAs which were derived from a single human mRNA source contained either 11 or 13 repeats, suggesting the representation of polymorphic CAG alleles transcribed from the homologous chromosome pair.

EXAMPLE 6

Large Scale Genotyping Survey for Expanded CAGrepeats

The possibility of identifying aberrant length CAG repeat sequences distinguishable from normal length polymorphism in the human α_(1A) Ca²⁺ channel subunit was examined via a large scale genotyping survey of ataxia patients. This technique is based on the premise that if trinucleotide expansion is responsible for SCA6, expansions would be observed at a relatively high frequency in affected individuals but would be absent or occur at very low frequency in non-disease alleles.

DNA samples from 475 unrelated non-ataxia individuals in the general population and 133 DNA samples from unrelated index cases known to have progressive cerebellar ataxia were analyzed. Using a pair of radiolabeled synthetic oligonucleotide primers flanking the CAG repeat sequence of the human α_(1A) Ca²⁺ channel subunit, the CAG repeat region of each sample was amplified and the size of the CAG repeat region was determined via gel electrophoresis. The repeat sizes of the ataxia group samples were compared with those obtained from the DNA of the general population samples.

Table I shows the distribution of the CAG repeat sizes in the α_(1A) Ca²⁺ channel subunit gene of the 133 index patients with cerebellar ataxia as well as the distribution of the CAG repeat sizes in the α_(1A) Ca²⁺ channel subunit gene of the 475 non-ataxia samples. The ethnic background of the control and patient populations included individuals of Caucasian, African American, Hispanic and Asian ancestry. Individuals from the general population displayed 10 alleles ranging from 4 to 16 CAG repeat units and a heterozygosity of 71%. In the cerebellar ataxia patients, the number of CAG repeats ranged in size from 7 to 27 with a heterozygosity of 74%. As can be seen in the allele size distribution, eight unrelated patients out of 133 ataxia index cases (6%) had a larger size allele of at least 21 CAG repeat units. Although the expansion was relatively small it was not observed in 475 individuals from the non-ataxia controls making it extremely unlikely to be normal length polymorphism (P<10⁻⁵ using Fisher's exact test).

TABLE 1 Comparison of the number of CAG repeat units on Ataxia and Non-Ataxia chromosomes Number of CAG Non-ataxia controls Ataxia index controls repeat units Number of chromosomes Number of chromosomes  4 21  0  5 0 0  6 4 0  7 65  27   8 2 2  9 0 0 10 0 0 11 398  91  12 150  57  13 264  73  14 39  7 15 6 1 16 1 0 17 0 0 18 0 0 19 0 0 20 0 0 21 0 1 22 0 5 23 0 1 . . . . . . . . . 27 0 1

The genomic DNA from these eight index cases was amplified by the S-5 primers, subcloned and sequenced. The number of CAG repeat units obtained from sequence analysis was consistent with an increase in the number of pure CAG repeat units in the α_(1A) Ca²⁺ channel subunit. The different number of CAG repeat units in these expanded alleles argues against a rare founder allele. The observation of aberrant alleles of expanded sizes in the ataxia population and their absence in the general population was consistent with the possibility that these expanded alleles represent the mutational basis in a fraction of the ataxia patients analyzed.

The method of large scale genotyping was effective i n identifying the CAG expansin in the α_(1A) Ca²⁺ channel subunit gene. Thus, this concept may be used in the search for other mutation types associated with triplet repeat disease phenomenon. Basically, one assumes that trinucleotide repeat expansion is associated with alleles at high frequency in disease phenotypes, but absent or at low frequency in non-disease phenotypes. Large scale genotyping, thus, is different from the approaches used for the identification of other human disease genes, including the positional cloning approach. In the positionaly cloning approach, a genetic linkage to a specific chromosomal region must be established prior to the isolation of the candidate disease gene. Positional cloning was used for the identification of the genes for Huntington disease, spinobulbar muscular atrophy, spinocerebellar ataxia type 1, spinocerebellar ataxia type 2, spinocerebellar ataxia type 3/Machado-Joseph disease, and the genes associated with Fragile X and myotonic muscular dystrophy.

The approach of the present invention also is different from random candidate gene approach for human disease, whereby no systematic strategy is used in the identification of genes. The random candidate gene approach was used in the identification of the dentatorubral-pallidoluysian atrophy/Haw-River syndrome gene. The strategy of the present invention is based on the observation that triplet repeat sequences in disease genes are polymorphic in length which makes them suitable for a large scale genotyping survey. The large scale genotyping approach identifies aberrant allele sizes in diseased individuals as compared with the non-disease population. This concept-driven strategy negates the need for prior establishment of specific genetic association (linkage) in family pedigrees as is employed as a first step in a positional cloning. The large scale genotyping strategy of the present invention is a direct-gene-to-disease-state approach.

In another object of the present invention, there is provided a method of identifying genes in which a disease-causing allele is due to trinucleotide repeat sequence instability, comprising the steps of: screening a library with an oligonucleotide having a triplet base repeat; identifying clones which have said triplet base repeat; sequencing said identified clones to determine sequences of nucleotides flanking said triplet base repeat; synthesizing primers complementary to said sequences of nucleotides flanking said triplet base repeat; isolating DNA from a large sampling of individuals, including diseased and non-diseased individuals; amplifying said isolated DNA with said primers to produce amplified triplet base repeat regions; determining a number of triplet base repeats in said triplet base repeat region for each of said individuals in said large sampling; determining whether triplet base repeat expansions are observed at a relatively high frequency in diseased individuals but are absent or occur at very low frequency in non-disease individuals, wherein if triplet base repeat expansions are observed at a relatively high frequency in diseased individuals but are absent or occur at very low frequency in non-disease individuals, it is likely that a disease-causing allele is due to trinucleotide repeat sequence instability.

EXAMPLE 7

Inheritance of Expanded Alleles in Ataxia Patients

Four of the index cases were from families where additional affected members have been clinically evaluated, and DNA could be obtained for genotypic analysis. Twenty-one family members participated in the study after informed consents were obtained. Fourteen of the 21 had clinical evidence of ataxia. In each of these families, the ataxia was inherited in an autosomal dominant manner with the age of onset ranging between 28 and 50 years.

Genotypic analyses of family members using the S-5 primers demonstrated that the expanded allele segregated with the disease phenotype in each family. For example, FIG. 4A shows the expanded allele with 27 repeats in the four affected individuals from the INSCA kindred but in none of the asymptomatic family members including a distantly related member (data not shown). In this kindred the age of onset ranged between 28 and 31 years, and three of the asymptomatic individuals were 41 years old or older. FIG. 4B shows that the expanded allele of 22 repeats was observed in all five affected members of the MS2SCA kindred. In the MDSCA kindred (FIG. 4C) an aberrant size allele of 23 CAG repeat was present in two brothers (II.1 and II.3) and a sister (II.2) with clinical ataxia but not in the asymptomatic daughter of II.1. In the SISCA family, shown in FIG. 4D, two affected members (IV.1 and III.7) separated by five meiotic events share the same number of 22 CAG repeats on their larger alleles. Tracing this allele through the pedigree indicates that their affected progenitors (III.5, II.2, II.4 and I.2) most likely have carried this expanded allele. The segregation of the expanded allele with the disease in these families is highly significant as evident by a cumulative haplotype lod score of 5.08 at a recombination frequency of zero when the genotypic data from affected individuals were analyzed using version 3.OP of the FASTLINK computer programs (see above)^(26,27). The lod scores for each kindred are summarized in TABLE 2. Taken together, t h e statistically significant finding that the expanded alleles are only observed in patients diagnosed with cerebellar ataxia but not in 475 non-ataxia controls and the clear cut association of these expanded alleles with disease demonstrate that the polyglutamine expansion in the α_(1A) voltage-dependent Ca²⁺ channel subunit is the cause of this late onset dominantly inherited ataxia.

TABLE 2 Lod scores from haplotype analysis Family Lod score at Theta = 0 INSCA 1.20 MDSCA 0.90 MS2SCA 1.49 SISCA 1.49 SUM 5.08

EXAMPLE 8

Clinical and Pathological Findings in Patients with CAG Repeat Expansion

The clinical features of the patients in the above-described families were very similar and consist predominantly of mild but slowly progressive cerebellar ataxia of the limbs and gait, dysarthria, nystagmus, and mild vibratory and proprioceptive sensory loss. The disease is very insidious and most patients do not realize they are affected initially but do describe a sense of momentary imbalance and “wooziness” when they take a quick turn or make a rapid movement. Typically, it is years after this initial sensation when the patients realize that they have developed permanent balance and coordination difficulties. The disease usually progresses over 20-30 years leading to impairment of gait and causing the patient to become wheel-chair bound. In the few older patients, choking has been observed suggesting involvement of the brain stem, and the disease has been the cause of death in several members of the MDSCA and MS2SCA kindreds. Symptoms develop generally when the patients are in their forties in the MDSCA, SISCA, and MS2SCA families where the repeat number is 22-23; however in the INSCA kindred where the expanded allele contains 27 repeats, the disease onset is between 28 and 31 years in all the affected individuals. Magnetic resonance imaging of the brain in affected individuals reveals isolated cerebellar atrophy. Detailed neuropathologic studies on two deceased members from the SISCA kindred showed marked cerebellar atrophy and very mild atrophy of the brain stem²⁸. Microscopic examination revealed severe loss of cerebellar Purkinje cells, moderate loss of granule cells and dentate nucleus neurons, and mild to moderate neuronal loss in the inferior olive.

The hereditary cerebellar ataxias are a clinically and genetically heterogenous group of neurological disorders associated with dysfunction of the cerebellum and its afferent and efferent connections. To date, six autosomal dominant spinocerebellar ataxias (SCAs) have been mapped to human chromosomes 6,12, 14, 16, 11, and 3 with the loci designated SCA1, SCA2, SCA3, SCA4, SCA5, and SCA7, respectively¹⁰. The map location of the genes in many families with dominantly inherited and progressive ataxias remains unknown. The mapping of the α_(1A) Ca²⁺ channel subunit to human chromosome 19p13 and the identification of the CAG repeat expansion in this channel as the mutational mechanism in four families define a new SCA locus on human chromosome 19p13 which can be designated SCA6.

In the past, the term SCA6 has been used to described dominantly inherited SCAs that did not map to any of the known loci^(29,30). This mapping nomenclature was revised to assign the SCA6 locus to the dominantly inherited ataxia mapping to chromosome 19p13 (HGM Nomenclature Committee). Hereditary paroxysmal cerebellar ataxia (HPCA) or episodic ataxia (EA) has also been mapped to the 19p13 region³¹⁻³². The locus for another episodic disease, familial hemiplegic migraine (FHM)³³, has been localized to 19p13 in the region where the gene for HPCA/EA was assigned. Patients with HPCA or EA typically have periodic ataxia with apparently normal coordination between attacks. This is reminiscent of the episodic sensation of unsteadiness described in patients years before the ataxia becomes a permanent finding. The only persistent abnormality on neurologic exam in HPCA/EA is the presence of nystagmus, a finding seen in all the patients. Brain imaging studies revealed that some HPCA/EA patients have cerebellar atrophy³¹. Interestingly, in several families with FHM, affected members have shown degenerative cerebellar atrophy which is associated with ataxia, nystagmus and other vestibulocerebellar ocular abnormalities, similar to those seen in HPCA/EA³⁴. The overlap in the phenotypes of these two disorders led to the hypothesis that HPCA/EA and FHM are allelic disorders possibly caused by a mutation in an ion channel gene because of the periodic nature of the symptoms^(32,34.)

Recently, Ophoff et al. reported four missense mutations in the human α_(1A) Ca²⁺ channel subunit gene in families with FHM and two mutations disrupting the reading frame of the same gene in two families with EA²⁴. These results and the present invention demonstrate that FHM, HPCA/EA and the progressive SCA6 are allelic disorders. The nature of the mutation (CAG repeat expansion in SCA6 versus protein truncation in HPCA/EA) affects the clinical course of the disease. Permanent and progressive cerebellar and brain stem dysfunction were observed in SCA6 whereas mild and intermittent cerebellar dysfunction was seen in HPCA/EA. This suggests that the glutamine expansion affects the function of the channel in a manner which triggers progressive neuronal loss. This may be via alteration of neurotransmitter release or by causing abnormal levels of intracellular Ca²⁺ leading to subsequent cell death^(21,35). At this time the pathogenic effects of each of these mutations with regard to periodic neurological dysfunction versus permanent and progressive disease cannot be determined and will have to await transgenic mouse models and neurophysiologic studies. Although other mutations in the CACNL1A4 gene in SCA6 families has not been excluded the highly significant association between expansion and disease phenotype (P<10⁻⁵) in eight independent ataxia families and the different number of repeats on expanded alleles in four families (in the absence of intergenerational instability) argue strongly that this is the disease causing mutation. It is also important to note that Ophoff and collegues²⁴ did not observe any expanded alleles in the 50 normal individuals they genotyped.

Although the mutational mechanism in SCA6 proved to involve an expansion of a translated CAG repeat like the other dominantly inherited progressive ataxias, it is not clear whether the pathogenic mechanism is similar. There are two key differences between the mutation in SCA6 and those causing SCA1, SCA2, SCA3, HD, DRPLA, and SBMA. First, the expanded mutant alleles in SCA6 (21-27 repeats) are remarkably smaller than the expanded alleles seen in any of the other neurodegenerative diseases (36-121 repeats) and are well within the normal range of polyglutamine tracts seen at the other loci in many unaffected individuals. Second, the CAG repeat expansion occurs in the coding region of a gene which is known to b e important for normal Purkinje cell function and survival^(19,25). This raises the possibility that the CAG expansion is exerting its pathogenic effect by directly interfering with the normal function of the α_(1A) calcium channel.

Voltage-dependent calcium channels mediate the entry of calcium into neurons and other excitable cells and play important roles in a variety of neuronal functions, including membrane excitability, neurotransmitter release, and gene expression³⁶. Calcium channels are multisubunit complexes with the channel activity mainly mediated by the pore-forming a₁ subunit, however, additional subunits including b, a₂/d, and g act as accessory proteins that regulate channel activity³⁶⁻³⁸. The cDNAs encoding six a₁ genes have been cloned and have been designated α_(1A,B,C,D,E) and S³⁹. The human gene characterized in the present invention is most homologous to the rabbit and rat α_(1A) isoforms^(19,20). The mapping assignment to human chromosome 19 is consistent with the previous mapping of the human sequence encoding the α_(1A) isoform to chromosome 19p13²²⁻²⁴. A combination of electrophysiologic and pharmacologic properties define four main types of high-threshold calcium channels in peripheral and central neurons of mammals⁴⁰. These are designated L, N, P, and Q, with the P-type channels being the predominant calcium channel in Purkinje cells, and the Q type being a prominent calcium current in cerebellar granule cells^(25,38). The cloned α_(1A) isoform has been shown to give rise to P and/or Q type calcium currents^(38,40). The additional isoforms identified may help resolve some of the functional differences observed for the P/Q type calcium currents. The pharmacologic as well as the electrophysiologic properties of the α_(1A) channel, together with its abundant expression in rat cerebellum emphasize its importance for calcium entry and homeostasis in Purkinje cells^(25,41).

Recently, the mouse homolog of the α_(1A) voltage-dependent subunit gene has been identified using a positional cloning strategy aimed at identifying the gene mutated in the tottering (tg) and leaner (tg^(la)) mice which show seizures and cerebellar ataxia⁴². This locus maps to mouse chromosome 8 in a region syntenic with human 19p13. The tg mutation, a C to T change at position 1802, causes a nonconserved proline to leucine substitution in a position very close to the conserved pore-lining domain in the extracellular segment of the second transmembrane domain. This mutation leads to a recessive neurological disorder with ataxia, motor- and absence-type seizures.

The tg^(la) mutation is a single G to A change in the splice donor consensus sequence at the 5′ end of an intron located in the C-terminus intracellular domain. This mutation gives rise to two aberrantly spliced mRNAs detected by RT-PCR; a larger fragment resulting from failure to splice out the intron and a smaller fragment resulting from skipping of one exon. Both transcripts are predicted to shift the reading frame and produce abnormal proteins. Homozygous tg^(la) mice, which have the splice mutation have more profound ataxia and cerebellar degeneration compared to the tg mice.

The findings that mutations in the α_(1A) Ca²⁺ channel are associated with cerebellar ataxia and Purkinje and granule cell degeneration in the mouse support the hypothesis that this channel is critical for normal Purkinje and granule cell function in the cerebellum. The recessive nature of the two mutations in the mouse and the fact that the tg^(la) mutation is predicted to generate an abnormal protein suggest that these mutations are causing the ataxia phenotype through a loss of function mechanism. The mutation in the tg^(la) mice alter the carboxy terminus portion of the channel just up stream from the position of the putative glutamine tract in the human gene. These data raise interesting questions about the mechanism by which a modest glutamine expansion in the human α_(1A) Ca²⁺ channel isoform leads to the cerebellar degeneration and ataxia. The dominant nature of the disease would suggest three possibilities: (1) loss of function due to haploinsufficiency, (2) a dominant negative effect due to the expansion, or (3) a novel gain of function as has been suggested in other diseases caused by CAG repeat expansions. The lack of ataxia phenotype in the tg and tg^(la) mice heterozygous for the mutation would argue against the loss of function hypothesis. However, this model can not be ruled out until it is confirmed that either mutation in the mouse truly leads to a loss of the α_(1A) Ca²⁺ channel function and that the heterozygous mice do not display ataxia nor Purkinje cell degeneration using careful quantitative measures. Given the transient and mild nature of the ataxia in some of the patients it could be extremely difficult to ascertain a mild and intermittent ataxia phenotype in the mice. A model invoking a dominant negative mechanism is compatible with the inheritance pattern in the human families and with data available so far on the tg mice. In this model, the small expansion of the glutamine tract could interfere with the normal function of the channel either by affecting its binding to synaptic proteins or by hindering its association with other accessory channel proteins that are known to modulate its activity. Given that the α_(1A) Ca²⁺ channel is now known to be important for normal Purkinje cell function based on electrophysiologic data⁴³ and the data in the tg mice, it is hard to argue that the glutamine expansion is conferring novel gain of function on the protein. The glutamine expansion most likely leads to aberrant channel function including the possibility of constitutive activation. The ultimate proof of the various models will await the generation of mice which lack the α_(1A) Ca²⁺ channel gene and mice which express an allele with a CAG expansion in the SCA6 disease range.

The genotype/phenotype correlation in SCA6 suggests that the expansion is quite deleterious given the dramatic difference in the age of onset (28-31 years) in every member of the family carrying the 27 repeats as compared to the other families (40-50 years) when the repeat size is in the 22-23 repeat range. Although the sample size is too small at this time to draw firm conclusion about genotype/phenotype correlation, it would be interesting to see if some patients with HPCA/EA, which is much milder than SCA6, would have even smaller expansions. In addition, it would be important to determine if different mutations in the α_(1A) Ca²⁺ channel lead to SCA6. The CAG repeat in SCA6 is stable without detectable mosaicism or intergenerational allele size changes. This is not surprising given that similar size CAG repeats at many other loci have been shown to be transmitted in a stable manner. However, the size of the repeat in the general population and the different sizes of expanded alleles in different SCA6 families suggest that some degree of instability does occur at this locus and that such instability has resulted in mutational expansions into the disease allele range.

In conclusion, the present invention demonstrates that a relatively small polyglutamine expansion in the human α_(1A) subunit of a Purkinjc cell type Ca²⁺ channel leads to Purkinje cell degeneration and cerebellar ataxia. The immediate implications of this finding are both clinical and biological. The observation that a relatively small CAG repeat expansion can lead to abnormal protein function provides a new concept about the effects of such repeats and the need to evaluate each carefully for possible pathogenic effects. Lastly, the expansion of a polyglutamine tract in a human calcium channel should provide insight about mechanisms of neurodegeneration as they pertain to calcium homeostasis and the possible role of such mechanisms in other glutamine-mediated neurodegenerative processes.

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Any patents or publications mentioned in this specification are indicative of the levels of those skilled in the art to which the invention pertains. These patents and publications are herein incorporated by reference to the same extent as if each individual publication was specifically and individually indicated to be incorporated by reference.

One skilled in the art will readily appreciate that the present invention is well adapted to carry out the objects and obtain the ends and advantages mentioned, as well as those inherent therein. The present examples along with the methods, procedures, treatments, molecules, and specific compounds described herein are presently representative of preferred embodiments, are exemplary, and are not intended as limitations on the scope of the invention. Changes therein and other uses will occur to those skilled in the art which are encompassed within the spirit of the invention as defined by the scope of the claims.

SEQUENCE LISTING (1) GENERAL INFORMATION: (iii) NUMBER OF SEQUENCES: 5 (2) INFORMATION FOR SEQ ID NO: 1 (i) SEQUENCE CHARACTERISTICS: (A) LENGTH: 25 base pairs (B) TYPE: nucleic acid (C) STRANDEDNESS: single-stranded (D) TOPOLOGY: linear (ii) MOLECULE TYPE: (A) DESCRIPTION: other nucleic acid (iii) HYPOTHETICAL: no (iv) ANTISENSE: no (ix) FEATURE: (A) NAME KEY: S-5-F1 (D) OTHER INFORMATION: oligonucleotide (xi) SEQUENCE DESCRIPTION: SEQ ID NO.: 1 CACGTGTCCT ATTCCCCTGT GATCC 25 (3) INFORMATION FOR SEQ ID NO: 2 (i) SEQUENCE CHARACTERISTICS: (A) LENGTH: 25 base pairs (B) TYPE: nucleic acid (C) STRANDEDNESS: single-stranded (D) TOPOLOGY: linear (ii) MOLECULE TYPE: (A) DESCRIPTION: other nucleic acid (iii) HYPOTHETICAL: no (iv) ANTISENSE: no (ix) FEATURE: (A) NAME KEY: S-5-R1 (D) OTHER INFORMATION: oligonucleotide (xi) SEQUENCE DESCRIPTION: SEQ ID NO.: 2 TGGGTACCTC CGAGGGCCGC TGGTG 25 (4) INFORMATION FOR SEQ ID NO: 3 (i) SEQUENCE CHARACTERISTICS: (A) LENGTH: 3632 base pairs (B) TYPE: nucleic acid (C) STRANDEDNESS: double-stranded (D) TOPOLOGY: linear (ii) MOLECULE TYPE: (A) DESCRIPTION: cDNA (iii) HYPOTHETICAL: no (iv) ANTISENSE: no (vi) ORIGINAL SOURCE: (A) ORGANISM: human (F) TISSUE TYPE: brain (vii) IMMEDIATE SOURCE: (A) LIBRARY: primary human brain cDNA (B) CLONE: BI-1-GGCAG (viii) POSITION IN GENOME: (A) CHROMOSOME/SEGMENT: 19p13 (xi) SEQUENCE DESCRIPTION: SEQ ID NO.: 3 GAATTCTTCC ACTCGACTTC ATAGTGGTCA GTGGGGCCCT GGTAGCCTTT GCCTTCACTG 60 GCAATAGCAA AGGAAAAGAC ATCAACACGA TTAAATCCCT CCGAGTCCTC CGGGTGCTAC 120 GACCTCTTAA AACCATCAAG CGGCTGCCAA AGCTCAAGGC TGTGTTTGAC TGTGTGGTGA 180 ACTCACTTAA AAACGTCTTC AACATCCTCA TCGTCTACAT GCTATTCATG TTCATCTTCG 240 CCGTGGTGGC TGTGCAGCTC TTCAAGGGGA AATTCTTCCA CTGCACTGAC GAGTCCAAAG 300 AGTTTGAGAA AGATTGTCGA GGCAAATACC TCCTCTACGA GAAGAATGAG GTGAAGGCGC 360 GAGACCGGGA GTGGAAGAAG TATGAATTCC ATTACGACAA TGTGCTGTGG GCTCTGCTGA 420 CCCTCTTCAC CGTGTCCACG GGAGAAGGCT GGCCACAGGT CCTCAAGCAT TCGGTGGACG 480 CCACCTTTGA GAACCAGGGC CCCAGCCCCG GGTACCGCAT GGAGATGTCC ATTTTCTACG 540 TCGTCTACTT TGTGGTGTTC CCCTTCTTCT TTGTCAATAT CTTTGTGGCC TTGATCATCA 600 TCACCTTCCA GGAGCAAGGG GACAAGATGA TGGAGGAATA CAGCCTGGAG AAAAATGAGA 660 GGGCCTGCAT TGATTTCGCC ATCAGCGCCA AGCCGCTGAC CCGACACATG CCGCAGAACA 720 AGCAGAGCTT CCAGTACCGC ATGTGGCAGT TCGTGGTGTC TCCGCCTTTC GAGTACACGA 780 TCATGGCCAT GATCGCCCTC AACACCATCG TGCTTATGAT GAAGTTCTAT GGGGCTTCTG 840 TTGCTTATGA AAATGCCCTG CGGGTGTTCA ACATCGTCTT CACCTCCCTC TTCTCTCTGG 900 AATGTGTGCT GAAAGTCATG GCTTTTGGGA TTCTGAATTA TTTCCGCGAT GCCTGGAACA 960 TCTTCGACTT TGTGACTGTT CTGGGCAGCA TCACCGATAT CCTCGTGACT GAGTTTGGGA 1020 ATAACTTCAT CAACCTGAGC TTTCTCCGCC TCTTCCGAGC TGCCCGGCTC ATCAAACTTC 1080 TCCGTCAGGG TTACACCATC CGCATTCTTC TCTGGACCTT TGTGCAGTCC TTCAAGGCCC 1140 TGCCTTATGT CTGTCTGCTG ATCGCCATGC TCTTCTTCAT CTATGCCATC ATTGGGATGC 1200 AGGTGTTTGG TAACATTGGC ATCGACGTGG AGGACGAGGA CAGTGATGAA GATGAGTTCC 1260 AAATCACTGA GCACAATAAC TTCCGGACCT TCTTCCAGGC CCTCATGCTT CTCTTCCGGA 1320 GTGCCACCGG GGAAGCTTGG CACAACATCA TGCTTTCCTG CCTCAGCGGG AAACCGTGTG 1380 ATAAGAACTC TGGCATCCTG ACTCGAGAGT GTGGCAATGA ATTTGCTTAT TTTTACTTTG 1440 TTTCCTTCAT CTTCCTCTGC TCGTTTCTGA TGCTGAATCT CTTTGTCGCC GTCATCATGG 1500 ACAACTTTGA GTACCTCACC CGAGACTCCT CCATCCTGGG CCCCCACCAC CTGGATGAGT 1560 ACGTGCGTGT CTGGGCCGAG TATGACCCCG CAGCTTGGGG CCGCATGCCT TACCTGGACA 1620 TGTATCAGAT GCTGAGACAC ATGTCTCCGC CCCTGGGTCT GGGGAAGAAG TGTCCGGCCA 1680 GAGTGGCTTA CAAGCGGCTT CTGCGGATGG ACCTGCCCGT CGCAGATGAC AACACCGTCC 1740 ACTTCAATTC CACCCTCATG GCTCTGATCC GCACAGCCCT GGACATCAAG ATTGCCAAGG 1800 GAGGAGCCGA CAAACAGCAG ATGGACGCTG AGCTGCGGAA GGAGATGATG GCGATTTGGC 1860 CCAATCTGTC CCAGAAGACG CTAGACCTGC TGGTCACACC TCACAAGTCC ACGGACCTCA 1920 CCGTGGGGAA GATCTACGCA GCCATGATGA TCATGGAGTA CTACCGGCAG AGCAAGGCCA 1980 AGAAGCTGCA GGCCATGCGC GAGGAGCAGG ACCGGACACC CCTCATGTTC CAGCGCATGG 2040 AGCCCCCGTC CCCAACGCAG GAAGGGGGAC CTGGCCAGAA CGCCCTCCCC TCCACCCAGC 2100 TGGACCCAGG AGGAGCCCTG ATGGCTCACG AAAGCGGCCT CAAGGAGAGC CCGTCCTGGG 2160 TGACCCAGCG TGCCCAGGAG ATGTTCCAGA AGACGGGCAC ATGGAGTCCG GAACAAGGCC 2220 CCCCTACCGA CATGCCCAAC AGCCAGCCTA ACTCTCAGTC CGTGGAGATG CGAGAGATGG 2280 GCAGAGATGG CTACTCCGAC AGCGAGCACT ACCTCCCCAT GGAAGGCCAG GGCCGGGCTG 2340 CCTCCATGCC CCGCCTCCCT GCAGAGAACC AGAGGAGAAG GGGCCGGCCA CGTGGGAATA 2400 ACCTCAGTAC CATCTCAGAC ACCAGCCCCA TGAAGCGTTC AGCCTCCGTG CTGGGCCCCA 2460 AGGCCCGACG CCTGGACGAT TACTCGCTGG AGCGGGTCCC GCCCGAGGAG AACCAGCGGC 2520 ACCACCAGCG GCGCCGCGAC CGCAGCCACC GCGCCTCTGA GCGCTCCCTG GGCCGCTACA 2580 CCGATGTGGA CACAGGCTTG GGGACAGACC TGAGCATGAC CACCCAATCC GGGGACCTGC 2640 CGTCGAAGGA GCGGGACCAG GAGCGGGGCC GGCCCAAGGA TCGGAAGCAT CGACAGCACC 2700 ACCACCACCA CCACCACCAC CACCATCCCC CGCCCCCCGA CAAGGACCGC TATGCCCAGG 2760 AACGGCCGGA CCACGGCCGG GCACGGGCTC GGGACCAGCG CTGGTCCCGC TCGCCCAGCG 2820 AGGGCCGAGA GCACATGGCG CACCGGCAGG GCAGTAGTTC CGTAAGTGGA AGCCCAGCCC 2880 CCTCAACATC TGGTACCAGC ACTCCGCGGC GGGGCCGCCG CCAGCTCCCC CAGACCCCCT 2940 CCACCCCCCG GCCACACGTG TCCTATTCCC CTGTGATCCG TAAGGCCGGC GGCTCGGGGC 3000 CCCCGCAGCA GCAGCAGCAG CAGCAGCAGC AGCAGCAGCA GGCGGTGGCC AGGCCGGGCC 3060 GGGCGGCCAC CAGCGGCCCT CGGAGGTACC CAGGCCCCAC GGCCGAGCCT CTGGCCGGAG 3120 ATCGGCCGCC CACGGGGGGC CACAGCAGCG GCCGCTCGCC CAGGATGGAG AGGCGGGTCC 3180 CAGGCCCGGC CCGGAGCGAG TCCCCCAGGG CCTGTCGACA CGGCGGGGCC CGGTGGCCGG 3240 CATCTGGCCC GCACGTGTCC GAGGGGCCCC CGGGTCCCCG GCACCATGGC TACTACCGGG 3300 GCTCCGACTA CGACGAGGCC GATGGCCCGG GCAGCGGGGG CGGCGAGGAG GCCATGGCCG 3360 GGGCCTACGA CGCGCCACCC CCCGTACGAC ACGCGTCCTC GGGCGCCACC GGGCGCTCGC 3420 CCAGGACTCC CCGGGCCTCG GGCCCGGCCT GCGCCTCGCC TTCTCGGCAC GGCCGGCGAC 3480 TCCCCAACGG CTACTACCCG GCGCACGGAC TGGCCAGGCC CCGCGGGCCG GGCTCCAGGA 3540 AGGGCCTGCA CGAACCCTAC AGCGAGAGTG ACGATGATTG GTGCTAAGCC CGGGCGAGGG 3600 AATTCCTTTT TTTTTTTTTT TTTTTTTTTT TT 3632 (5) INFORMATION FOR SEQ ID NO: 4 (i) SEQUENCE CHARACTERISTICS: (A) LENGTH: 3632 base pairs (B) TYPE: nucleic acid (C) STRANDEDNESS: double-stranded (D) TOPOLOGY: linear (ii) MOLECULE TYPE: (A) DESCRIPTION: cDNA (iii) HYPOTHETICAL: no (iv) ANTISENSE: no (vi) ORIGINAL SOURCE (A) ORGANISM: human (F) TISSUE TYPE: brain (vii) IMMEDIATE SOURCE: (A) LIBRARY: primary human brain cDNA (B) CLONE: BI-1(VI)-GGCAG (viii) POSITION IN GENOME: (A) CHROMOSOME/SEGMENT: 19p13 (xi) SEQUENCE DESCRIPTION: SEQ ID NO.: 4 GAATTCTTCC ACTCGACTTC ATAGTGGTCA GTGGGGCCCT GGTAGCCTTT GCCTTCACTG 60 GCAATAGCAA AGGAAAAGAC ATCAACACGA TTAAATCCCT CCGAGTCCTC CGGGTGCTAC 120 GACCTCTTAA AACCATCAAG CGGCTGCCAA AGCTCAAGGC TGTGTTTGAC TGTGTGGTGA 180 ACTCACTTAA AAACGTCTTC AACATCCTCA TCGTCTACAT GCTATTCATG TTCATCTTCG 240 CCGTGGTGGC TGTGCAGCTC TTCAAGGGGA AATTCTTCCA CTGCACTGAC GAGTCCAAAG 300 AGTTTGAGAA AGATTGTCGA GGCAAATACC TCCTCTACGA GAAGAATGAG GTGAAGGCGC 360 GAGACCGGGA GTGGAAGAAG TATGAATTCC ATTACGACAA TGTGCTGTGG GCTCTGCTGA 420 CCCTCTTCAC CGTGTCCACG GGAGAAGGCT GGCCACAGGT CCTCAAGCAT TCGGTGGACG 480 CCACCTTTGA GAACCAGGGC CCCAGCCCCG GGTACCGCAT GGAGATGTCC ATTTTCTACG 540 TCGTCTACTT TGTGGTGTTC CCCTTCTTCT TTGTCAATAT CTTTGTGGCC TTGATCATCA 600 TCACCTTCCA GGAGCAAGGG GACAAGATGA TGGAGGAATA CAGCCTGGAG AAAAATGAGA 660 GGGCCTGCAT TGATTTCGCC ATCAGCGCCA AGCCGCTGAC CCGACACATG CCGCAGAACA 720 AGCAGAGCTT CCAGTACCGC ATGTGGCAGT TCGTGGTGTC TCCGCCTTTC GAGTACACGA 780 TCATGGCCAT GATCGCCCTC AACACCATCG TGCTTATGAT GAAGTTCTAT GGGGCTTCTG 840 TTGCTTATGA AAATGCCCTG CGGGTGTTCA ACATCGTCTT CACCTCCCTC TTCTCTCTGG 900 AATGTGTGCT GAAAGTCATG GCTTTTGGGA TTCTGAATTA TTTCCGCGAT GCCTGGAACA 960 TCTTCGACTT TGTGACTGTT CTGGGCAGCA TCACCGATAT CCTCGTGACT GAGTTTGGGA 1020 ATAACTTCAT CAACCTGAGC TTTCTCCGCC TCTTCCGAGC TGCCCGGCTC ATCAAACTTC 1080 TCCGTCAGGG TTACACCATC CGCATTCTTC TCTGGACCTT TGTGCAGTCC TTCAAGGCCC 1140 TGCCTTATGT CTGTCTGCTG ATCGCCATGC TCTTCTTCAT CTATGCCATC ATTGGGATGC 1200 AGGTGTTTGG TAACATTGGC ATCGACGTGG AGGACGAGGA CAGTGATGAA GATGAGTTCC 1260 AAATCACTGA GCACAATAAC TTCCGGACCT TCTTCCAGGC CCTCATGCTT CTCTTCCGGA 1320 GTGCCACCGG GGAAGCTTGG CACAACATCA TGCTTTCCTG CCTCAGCGGG AAACCGTGTG 1380 ATAAGAACTC TGGCATCCTG ACTCGAGAGT GTGGCAATGA ATTTGCTTAT TTTTACTTTG 1440 TTTCCTTCAT CTTCCTCTGC TCGTTTCTGA TGCTGAATCT CTTTGTCGCC GTCATCATGG 1500 ACAACTTTGA GTACCTCACC CGAGACTCCT CCATCCTGGG CCCCCACCAC CTGGATGAGT 1560 ACGTGCGTGT CTGGGCCGAG TATGACCCCG CAGCTTGCGG TCGGATTCAT TATAAGGATA 1620 TGTACAGTTT ATTACGAGTA ATATCTCCCC CTCTCGGCTT AGGCAAGAAA TGTCCTCATA 1680 GGGTTGCTTG CAAGCGGCTT CTGCGGATGG ACCTGCCCGT CGCAGATGAC AACACCGTCC 1740 ACTTCAATTC CACCCTCATG GCTCTGATCC GCACAGCCCT GGACATCAAG ATTGCCAAGG 1800 GAGGAGCCGA CAAACAGCAG ATGGACGCTG AGCTGCGGAA GGAGATGATG GCGATTTGGC 1860 CCAATCTGTC CCAGAAGACG CTAGACCTGC TGGTCACACC TCACAAGTCC ACGGACCTCA 1920 CCGTGGGGAA GATCTACGCA GCCATGATGA TCATGGAGTA CTACCGGCAG AGCAAGGCCA 1980 AGAAGCTGCA GGCCATGCGC GAGGAGCAGG ACCGGACACC CCTCATGTTC CAGCGCATGG 2040 AGCCCCCGTC CCCAACGCAG GAAGGGGGAC CTGGCCAGAA CGCCCTCCCC TCCACCCAGC 2100 TGGACCCAGG AGGAGCCCTG ATGGCTCACG AAAGCGGCCT CAAGGAGAGC CCGTCCTGGG 2160 TGACCCAGCG TGCCCAGGAG ATGTTCCAGA AGACGGGCAC ATGGAGTCCG GAACAAGGCC 2220 CCCCTACCGA CATGCCCAAC AGCCAGCCTA ACTCTCAGTC CGTGGAGATG CGAGAGATGG 2280 GCAGAGATGG CTACTCCGAC AGCGAGCACT ACCTCCCCAT GGAAGGCCAG GGCCGGGCTG 2340 CCTCCATGCC CCGCCTCCCT GCAGAGAACC AGAGGAGAAG GGGCCGGCCA CGTGGGAATA 2400 ACCTCAGTAC CATCTCAGAC ACCAGCCCCA TGAAGCGTTC AGCCTCCGTG CTGGGCCCCA 2460 AGGCCCGACG CCTGGACGAT TACTCGCTGG AGCGGGTCCC GCCCGAGGAG AACCAGCGGC 2520 ACCACCAGCG GCGCCGCGAC CGCAGCCACC GCGCCTCTGA GCGCTCCCTG GGCCGCTACA 2580 CCGATGTGGA CACAGGCTTG GGGACAGACC TGAGCATGAC CACCCAATCC GGGGACCTGC 2640 CGTCGAAGGA GCGGGACCAG GAGCGGGGCC GGCCCAAGGA TCGGAAGCAT CGACAGCACC 2700 ACCACCACCA CCACCACCAC CACCATCCCC CGCCCCCCGA CAAGGACCGC TATGCCCAGG 2760 AACGGCCGGA CCACGGCCGG GCACGGGCTC GGGACCAGCG CTGGTCCCGC TCGCCCAGCG 2820 AGGGCCGAGA GCACATGGCG CACCGGCAGG GCAGTAGTTC CGTAAGTGGA AGCCCAGCCC 2880 CCTCAACATC TGGTACCAGC ACTCCGCGGC GGGGCCGCCG CCAGCTCCCC CAGACCCCCT 2940 CCACCCCCCG GCCACACGTG TCCTATTCCC CTGTGATCCG TAAGGCCGGC GGCTCGGGGC 3000 CCCCGCAGCA GCAGCAGCAG CAGCAGCAGC AGCAGCAGGC AGCGGTGGCC AGGCCGGGCC 3060 GGGCGGCCAC CAGCGGCCCT CGGAGGTACC CAGGCCCCAC GGCCGAGCCT CTGGCCGGAG 3120 ATCGGCCGCC CACGGGGGGC CACAGCAGCG GCCGCTCGCC CAGGATGGAG AGGCGGGTCC 3180 CAGGCCCGGC CCGGAGCGAG TCCCCCAGGG CCTGTCGACA CGGCGGGGCC CGGTGGCCGG 3240 CATCTGGCCC GCACGTGTCC GAGGGGCCCC CGGGTCCCCG GCACCATGGC TACTACCGGG 3300 GCTCCGACTA CGACGAGGCC GATGGCCCGG GCAGCGGGGG CGGCGAGGAG GCCATGGCCG 3360 GGGCCTACGA CGCGCCACCC CCCGTACGAC ACGCGTCCTC GGGCGCCACC GGGCGCTCGC 3420 CCAGGACTCC CCGGGCCTCG GGCCCGGCCT GCGCCTCGCC TTCTCGGCAC GGCCGGCGAC 3480 TCCCCAACGG CTACTACCCG GCGCACGGAC TGGCCAGGCC CCGCGGGCCG GGCTCCAGGA 3540 AGGGCCTGCA CGAACCCTAC AGCGAGAGTG ACGATGATTG GTGCTAAGCC CGGGCGAGGG 3600 AATTCCTTTT TTTTTTTTTT TTTTTTTTTT TT 3632 (6) INFORMATION FOR SEQ ID NO: 5 (i) SEQUENCE CHARACTERISTICS: (A) LENGTH: 3596 base pairs (B) TYPE: nucleic acid (C) STRANDEDNESS: double-stranded (D) TOPOLOGY: linear (ii) MOLECULE TYPE: (A) DESCRIPTION: cDNA (iii) HYPOTHETICAL: no (iv) ANTISENSE: no (vi) ORIGINAL SOURCE: (A) ORGANISM: human (F) TISSUE TYPE: brain (vii) IMMEDIATE SOURCE: (A) LIBRARY: primary human brain cDNA (B) CLONE: BI-1(V2)-GGCAG (viii) POSITION IN GENOME: (A) CHROMOSOME/SEGMENT: 19p13 (ix) FEATURE: (xi) SEQUENCE DESCRIPTION: SEQ ID NO.: 5 GAATTCTTCC ACTCGACTTC ATAGTGGTCA GTGGGGCCCT GGTAGCCTTT GCCTTCACTG 60 GCAATAGCAA AGGAAAAGAC ATCAACACGA TTAAATCCCT CCGAGTCCTC CGGGTGCTAC 120 GACCTCTTAA AACCATCAAG CGGCTGCCAA AGCTCAAGGC TGTGTTTGAC TGTGTGGTGA 180 ACTCACTTAA AAACGTCTTC AACATCCTCA TCGTCTACAT GCTATTCATG TTCATCTTCG 240 CCGTGGTGGC TGTGCAGCTC TTCAAGGGGA AATTCTTCCA CTGCACTGAC GAGTCCAAAG 300 AGTTTGAGAA AGATTGTCGA GGCAAATACC TCCTCTACGA GAAGAATGAG GTGAAGGCGC 360 GAGACCGGGA GTGGAAGAAG TATGAATTCC ATTACGACAA TGTGCTGTGG GCTCTGCTGA 420 CCCTCTTCAC CGTGTCCACG GGAGAAGGCT GGCCACAGGT CCTCAAGCAT TCGGTGGACG 480 CCACCTTTGA GAACCAGGGC CCCAGCCCCG GGTACCGCAT GGAGATGTCC ATTTTCTACG 540 TCGTCTACTT TGTGGTGTTC CCCTTCTTCT TTGTCAATAT CTTTGTGGCC TTGATCATCA 600 TCACCTTCCA GGAGCAAGGG GACAAGATGA TGGAGGAATA CAGCCTGGAG AAAAATGAGA 660 GGGCCTGCAT TGATTTCGCC ATCAGCGCCA AGCCGCTGAC CCGACACATG CCGCAGAACA 720 AGCAGAGCTT CCAGTACCGC ATGTGGCAGT TCGTGGTGTC TCCGCCTTTC GAGTACACGA 780 TCATGGCCAT GATCGCCCTC AACACCATCG TGCTTATGAT GAAGTTCTAT GGGGCTTCTG 840 TTGCTTATGA AAATGCCCTG CGGGTGTTCA ACATCGTCTT CACCTCCCTC TTCTCTCTGG 900 AATGTGTGCT GAAAGTCATG GCTTTTGGGA TTCTGAATTA TTTCCGCGAT GCCTGGAACA 960 TCTTCGACTT TGTGACTGTT CTGGGCAGCA TCACCGATAT CCTCGTGACT GAGTTTGGGA 1020 ATAACTTCAT CAACCTGAGC TTTCTCCGCC TCTTCCGAGC TGCCCGGCTC ATCAAACTTC 1080 TCCGTCAGGG TTACACCATC CGCATTCTTC TCTGGACCTT TGTGCAGTCC TTCAAGGCCC 1140 TGCCTTATGT CTGTCTGCTG ATCGCCATGC TCTTCTTCAT CTATGCCATC ATTGGGATGC 1200 AGGTGTTTGG TAACATTGGC ATCGACGTGG AGGACGAGGA CAGTGATGAA GATGAGTTCC 1260 AAATCACTGA GCACAATAAC TTCCGGACCT TCTTCCAGGC CCTCATGCTT CTCTTCCGGA 1320 GTGCCACCGG GGAAGCTTGG CACAACATCA TGCTTTCCTG CCTCAGCGGG AAACCGTGTG 1380 ATAAGAACTC TGGCATCCTG ACTCGAGAGT GTGGCAATGA ATTTGCTTAT TTTTACTTTG 1440 TTTCCTTCAT CTTCCTCTGC TCGTTTCTGA TGCTGAATCT CTTTGTCGCC GTCATCATGG 1500 ACAACTTTGA GTACCTCACC CGAGACTCCT CCATCCTGGG CCCCCACCAC CTGGATGAGT 1560 ACGTGCGTGT CTGGGCCGAG TATGACCCCG CAGCTTGGGG CCGCATGCCT TACCTGGACA 1620 TGTATCAGAT GCTGAGACAC ATGTCTCCGC CCCTGGGTCT GGGGAAGAAG TGTCCGGCCA 1680 GAGTGGCTTA CAAGCGGCTT CTGCGGATGG ACCTGCCCGT CGCAGATGAC AACACCGTCC 1740 ACTTCAATTC CACCCTCATG GCTCTGATCC GCACAGCCCT GGACATCAAG ATTGCCAAGG 1800 GAGGAGCCGA CAAACAGCAG ATGGACGCTG AGCTGCGGAA GGAGATGATG GCGATTTGGC 1860 CCAATCTGTC CCAGAAGACG CTAGACCTGC TGGTCACACC TCACAAGTCC ACGGACCTCA 1920 CCGTGGGGAA GATCTACGCA GCCATGATGA TCATGGAGTA CTACCGGCAG AGCAAGGCCA 1980 AGAAGCTGCA GGCCATGCGC GAGGAGCAGG ACCGGACACC CCTCATGTTC CAGCGCATGG 2040 AGCCCCCGTC CCCAACGCAG GAAGGGGGAC CTGGCCAGAA CGCCCTCCCC TCCACCCAGC 2100 TGGACCCAGG AGGAGCCCTG ATGGCTCACG AAAGCGGCCT CAAGGAGAGC CCGTCCTGGG 2160 TGACCCAGCG TGCCCAGGAG ATGTTCCAGA AGACGGGCAC ATGGAGTCCG GAACAAGGCC 2220 CCCCTACCGA CATGCCCAAC AGCCAGCCTA ACTCTCAGTC CGTGGAGATG CGAGAGATGG 2280 GCAGAGATGG CTACTCCGAC AGCGAGCACT ACCTCCCCAT GGAAGGCCAG GGCCGGGCTG 2340 CCTCCATGCC CCGCCTCCCT GCAGAGAACC AGACCATCTC AGACACCAGC CCCATGAAGC 2400 GTTCAGCCTC CGTGCTGGGC CCCAAGGCCC GACGCCTGGA CGATTACTCG CTGGAGCGGG 2460 TCCCGCCCGA GGAGAACCAG CGGCACCACC AGCGGCGCCG CGACCGCAGC CACCGCGCCT 2520 CTGAGCGCTC CCTGGGCCGC TACACCGATG TGGACACAGG CTTGGGGACA GACCTGAGCA 2580 TGACCACCCA ATCCGGGGAC CTGCCGTCGA AGGAGCGGGA CCAGGAGCGG GGCCGGCCCA 2640 AGGATCGGAA GCATCGACAG CACCACCACC ACCACCACCA CCACCACCAT CCCCCGCCCC 2700 CCGACAAGGA CCGCTATGCC CAGGAACGGC CGGACCACGG CCGGGCACGG GCTCGGGACC 2760 AGCGCTGGTC CCGCTCGCCC AGCGAGGGCC GAGAGCACAT GGCGCACCGG CAGGGCAGTA 2820 GTTCCGTAAG TGGAAGCCCA GCCCCCTCAA CATCTGGTAC CAGCACTCCG CGGCGGGGCC 2880 GCCGCCAGCT CCCCCAGACC CCCTCCACCC CCCGGCCACA CGTGTCCTAT TCCCCTGTGA 2940 TCCGTAAGGC CGGCGGCTCG GGGCCCCCGC AGCAGCAGCA GCAGCAGCAG CAGCAGCAGC 3000 AGCAGGCGGT GGCCAGGCCG GGCCGGGCGG CCACCAGCGG CCCTCGGAGG TACCCAGGCC 3060 CCACGGCCGA GCCTCTGGCC GGAGATCGGC CGCCCACGGG GGGCCACAGC AGCGGCCGCT 3120 CGCCCAGGAT GGAGAGGCGG GTCCCAGGCC CGGCCCGGAG CGAGTCCCCC AGGGCCTGTC 3180 GACACGGCGG GGCCCGGTGG CCGGCATCTG GCCCGCACGT GTCCGAGGGG CCCCCGGGTC 3240 CCCGGCACCA TGGCTACTAC CGGGGCTCCG ACTACGACGA GGCCGATGGC CCGGGCAGCG 3300 GGGGCGGCGA GGAGGCCATG GCCGGGGCCT ACGACGCGCC ACCCCCCGTA CGACACGCGT 3360 CCTCGGGCGC CACCGGGCGC TCGCCCAGGA CTCCCCGGGC CTCGGGCCCG GCCTGCGCCT 3420 CGCCTTCTCG GCACGGCCGG CGACTCCCCA ACGGCTACTA CCCGGCGCAC GGACTGGCCA 3480 GGCCCCGCGG GCCGGGCTCC AGGAAGGGCC TGCACGAACC CTACAGCGAG AGTGACGATG 3540 ATTGGTGCTA AGCCCGGGCG AGGGAATTCC TTTTTTTTTT TTTTTTTTTT TTTTTT 3596 

What is claimed is:
 1. A method of determining whether an individual has or is at risk for developing spinocerebellar ataxia type 6 (SCA-6), comprising the step of analyzing test genomic DNA from said individual to determine a number of CAG nucleotide repeat units present in an α_(1A) calcium channel subunit gene in said DNA, wherein an individual has or is at risk for developing spinocerebellar ataxia type 6 if said number of CAG nucleotide repeat units in said α_(1A) calcium channel subunit gene is greater than
 20. 2. The method of claim 1, wherein said analyzing comprises the step of: amplifying by polymerase chain reaction said CAG nucleotide repeat units present in said test genomic DNA using at least one oligonucleotide primer capable of amplifying a CAG nucleotide repeat unit present in the α_(1A) calcium channel subunit gene, thereby producing amplified test genomic DNA fragments.
 3. The method of claim 2, wherein said analyzing further comprises separating said amplified test genomic DNA fragments by gel electrophoresis.
 4. The method of claim 2, wherein said oligonucleotide primer(s) are radiolabeled.
 5. The method of claim 2, wherein said oligonucleotide primer(s) are selected from the group consisting of SEQ ID No. 1 and SEQ ID No.
 2. 6. A method of determining that an individual does not have and is not at risk for developing spinocerebellar ataxia type 6, comprising the steps of: analyzing test genomic DNA from said individual to determine a number of CAG nucleotide repeat units present in an α_(1A) calcium channel subunit gene in said DNA, wherein when the number of CAG nucleotide repeat units is less than 7, said individual does not have and is not at risk for developing spinocerebellar ataxia type
 6. 7. The method of claim 6, wherein said analyzing comprises the step of: amplifying by polymerase chain reaction said CAG nucleotide repeat units present in said test genomic DNA using at least one oligonucleotide primer capable of amplifying a CAG nucleotide repeat unit present in the α_(1A) calcium channel subunit gene, thereby producing amplified test genomic DNA fragments.
 8. The method of claim 7 wherein said amplified test genomic DNA fragments are separated by gel electrophoresis.
 9. The method of claim 7, wherein said oligonucleotide primer(s) are radiolabeled.
 10. The method of claim 7, wherein said oligonucleotide primer(s) are selected from the group consisting of SEQ ID No. 1 and SEQ ID No.
 2. 